Detalles del proyecto
Descripción
PROJECT SUMMARY / ABSTRACT
The Phase I STTR grant proposal aims to address the escalating global health challenge posed by Alzheimer's
disease (AD) by targeting TAK1 as a novel drug target. Currently, there is a lack of effective therapies to slow or
prevent disease progression. Identification of new drug targets involved in the pathogenesis of AD is essential
to expand treatment options and identify therapies that have the potential to improve the lives of AD patients. In
collaboration with Dr. Jun Ninomiya-Tsuji at North Carolina State University, this Phase I STTR builds on our
foundational studies that demonstrate the therapeutic potential of targeting TAK1. Our preliminary studies shave
shown that TAK1 phosphorylation (activation of the kinase) is significantly upregulated in aged WT and APP/PS1
mice, and that conditional TAK1 knockout in hippocampal neurons significantly reduces cognitive decline in this
mouse model. Further validation in the PS19 tauopathy model showed that TAK1 KO reduced neuronal death in
the dorsal dentate gyrus, indicating TAK1 is a critical mediator of non-canonical signaling within neurons and can
regulate neuronal necroptosis in AD mouse models. These foundational observations lay the groundwork for this
Phase I STTR. Utilizing EydisBio’s patented first-in-class TAK1 inhibitors, this proposal will identify suitable TAK1
inhibitors with optimal central nervous system blood-brain barrier penetrance that can be further advanced into
in vivo testing in the PS19 mouse model. Successful outcomes of this proposal would be the identification of at
least 1 pre-clinical candidate that demonstrates optimal target product profile attributes for further advancement
into efficacy and IND-enabling safety studies using funds provided by the NIH through a Phase II SBIR/STTR
grant.
The Phase I STTR grant proposal aims to address the escalating global health challenge posed by Alzheimer's
disease (AD) by targeting TAK1 as a novel drug target. Currently, there is a lack of effective therapies to slow or
prevent disease progression. Identification of new drug targets involved in the pathogenesis of AD is essential
to expand treatment options and identify therapies that have the potential to improve the lives of AD patients. In
collaboration with Dr. Jun Ninomiya-Tsuji at North Carolina State University, this Phase I STTR builds on our
foundational studies that demonstrate the therapeutic potential of targeting TAK1. Our preliminary studies shave
shown that TAK1 phosphorylation (activation of the kinase) is significantly upregulated in aged WT and APP/PS1
mice, and that conditional TAK1 knockout in hippocampal neurons significantly reduces cognitive decline in this
mouse model. Further validation in the PS19 tauopathy model showed that TAK1 KO reduced neuronal death in
the dorsal dentate gyrus, indicating TAK1 is a critical mediator of non-canonical signaling within neurons and can
regulate neuronal necroptosis in AD mouse models. These foundational observations lay the groundwork for this
Phase I STTR. Utilizing EydisBio’s patented first-in-class TAK1 inhibitors, this proposal will identify suitable TAK1
inhibitors with optimal central nervous system blood-brain barrier penetrance that can be further advanced into
in vivo testing in the PS19 mouse model. Successful outcomes of this proposal would be the identification of at
least 1 pre-clinical candidate that demonstrates optimal target product profile attributes for further advancement
into efficacy and IND-enabling safety studies using funds provided by the NIH through a Phase II SBIR/STTR
grant.
| Estado | Activo |
|---|---|
| Fecha de inicio/Fecha fin | 15/9/24 → 31/5/25 |
| Enlaces | https://reporter.nih.gov/project-details/11007130 |
Financiación
- National Institute on Aging: USD506,267.00
!!!ASJC Scopus Subject Areas
- Neurología clínica
- Neurología
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